Effect of bile on the oral absorption of halofantrine in polyethylene glycol 400 and polysorbate 80 formulations dosed to bile duct cannulated rats

Objectives The aim of this study was to examine the effects of bile on the oral absorption of the poorly water‐soluble compound, halofantrine, when administered to rats in vehicles consisting of the co‐solvent polyethylene glycol 400 (PEG 400) alone or in mixtures with the surfactant polysorbate 80 (PS 80) (95 : 5; 85 : 15; 75 : 25 PEG 400 : PS 80). Methods Halofantrine (17.5 mg/kg) was administered to bile duct cannulated (BDC) and sham‐operated rats in a fixed vehicle volume of 5 ml/kg. Key findings The bioavailability of halofantrine was significantly lower in BDC rats when dosed with 0–5% PS 80 in PEG 400 compared with BDC rats dosed with >15% PS 80. Increasing the concentration of PS 80 to 15–100% eliminated this difference. A possible explanation for the lower bioavailability of halofantrine in BDC rats when dosed in pure PEG 400 could be the dilution of the vehicle by intestinal fluids, decreased transit time and precipitation in the gastrointestinal tract upon dilution of PEG 400. Conclusions The addition of PS 80 to the formulation increased its solubilising power upon dilution and may have inhibited precipitation and substituted the absence of bile above a certain level. Adjusting the level of surfactant in drug formulations could therefore be used to minimise variability in the bioavailability from co‐solvent systems based upon differences in bile concentration between individuals.     

Respiratory Arrest as Main Determinant of Toxicity due to Overdose with Different β–Blockers in Rats

Propranolol, timolol and sotalol were compared regarding their toxicological effects on the cardiovascular and respiratory system. Each drug was administered intravenously to anaesthetized spontaneously breathing and artificially ventilated rats. After the start of infusion in spontaneously breathing rats each drug induced an expected decrease in arterial blood pressure and heart rate. An increase in PQ, QRS and QT interval was observed. From 5/8 of the survival time onwards these changes were accentuated. PaO₂, pH and respiratory rate decreased and PaCO₂ increased. The rats died as a result of respiratory arrest. Artificial ventilation of rats infused with the same doses increased the survival time significantly. The total doses administered before the animals died as a result of cardiovascular failure were significantly higher for each drug. The initial decreases in arterial blood pressure and heart rate were similar to those in spontaneously breathing rats. Thereafter, significantly smaller decreases were observed. The increases in PQ, QRS and QT interval were significantly less than in spontaneously breathing rats. Blood gases remained unchanged except for a decrease in pH in case of timolol     

Pharmacokinetics and first-pass effects of liquiritigenin in rats: low bioavailability is primarily due to extensive gastrointestinal first-pass effect

1. Pharmacokinetics of liquiritigenin, a candidate for inflammatory liver disease, and its two glucuronide conjugates, M1 and M2, were evaluated in rats. The hepatic and gastrointestinal first-pass effects of liquiritigenin were also evaluated in rats.

2. After oral administration of liquiritigenin at a dose of 20?mg kg^?1, 1.07% of the dose was not absorbed from the gastrointestinal tract up to 24?h, and the F-value was only 6.68%. In vitro metabolism of liquiritigenin in S9 fractions of rat tissues showed that the liver and intestine were major tissues responsible for glucuronidation of liquiritigenin. The hepatic and gastrointestinal first-pass effects of liquiritigenin were approximately 3.67% and 92.5% of the oral dose, respectively.

3. Although the hepatic first-pass effect of liquiritigenin after absorption into the portal vein was 57.1%, the value was only 3.67% of the oral dose due to extensive gastrointestinal first-pass effect in rats. Therefore, the low F-value of liquiritigenin in rats was primarily attributable to an extensive gastrointestinal first-pass effect although liquiritigenin was well absorbed. Compared with rats, the higher F-value of liquiritigenin could be expected in humans.

     

Antidiuretic and antinatriuretic response to high salt load in normotensive Wistar‐Kyoto rats: Role of alpha‐1A‐adrenoreceptors

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Subchronic mycotoxicoses in rats. Histopathological changes and modulation of the sphinganine to sphingosine (Sa/So) ratio imbalance induced by Fusarium verticillioides culture material, due to the coexistence of aflatoxin B1 in the diet.

Mycotoxicoses are diseases caused by consumption of diets contaminated with mycotoxins, a special class of fungal secondary metabolites. Fumonisin B1 (FB1) and aflatoxin B1 (AFB1), the main toxins synthesized by toxicogenic stocks of Fusarium spp. and Aspergillus spp., respectively, can coexist in grains and in its by-products. We investigated a probable synergism of a fumonisins-containing Fusarium verticillioides culture material and AFB1 in the induction of hepatocyte apoptosis in rats subchronically fed on a mixture of them. Furthermore, the possibility of modifications in the fumonisins-induced Sa/So ratio imbalance in tissues and urine from rats poisoned with this mycotoxin, due to the presence of AFB1 in the diet, was evaluated. The co-exposure to fumonisins and AFB1 produced a higher liver toxicity, with respect to their individual administration, inducing apoptosis and mitotic hepatocytes. There was an inversion of the typical Sa/So ratio in rats fed on the culture material as well as in those subjected to a diet co-contamined with fumonisins and AFB1. Moreover, the later had a synergistic effect in the induction of Sa/So variations in kidneys. Therefore, the mixture of fumonisins and AFB1 induced toxic responses which could not be considered a sum of the effects caused individually by these mycotoxins.